94611-94-6Relevant articles and documents
Metal-free cross-dehydrogenative coupling of aryl aldehydes to give symmetrical carboxylic anhydrides promoted by the TBHP/nBu4PBr system
Adib, Mehdi,Pashazadeh, Rahim,Rajai-Daryasarei, Saideh,Mirzaei, Peiman,Jamal Addin Gohari, Seyed
, p. 3071 - 3074 (2016)
A novel, efficient, and metal-free dual C–O bond formation reaction for the synthesis of carboxylic anhydrides from aryl aldehydes via cross-dehydrogenative coupling is described. Heating a mixture of aromatic aldehydes and an aqueous solution of tert-butyl hydroperoxide as oxidant in the presence of catalytic nBu4PBr in chlorobenzene at 80?°C for 3?h afforded the corresponding carboxylic anhydrides in good to excellent yields.
Cu-MOF: An efficient heterogeneous catalyst for the synthesis of symmetric anhydrides: Via the C-H bond activation of aldehydes
Ahmadzadeh, Zahra,Mokhtari, Javad,Rouhani, Morteza
, p. 24203 - 24208 (2018/07/25)
In this paper, an efficient and straightforward synthetic approach for the preparation of a number of symmetric carboxylic anhydrides was reported using Cu2(BDC)2(DABCO) as an efficient heterogeneous catalyst via the C-H bond activation of aldehydes with excellent yields and simple work up. This C-H bond activation reaction appears simple and convenient, has a wide substrate scope and makes use of cheap, abundant, and easily available reagents. The Cu-MOF catalyst was recycled and reused four times without any loss of catalytic activity.
Cu(I) catalyzed synthesis of anhydrides from aldehydes via CDC-pathway at ambient temperature
Nuree, Yasin,Singha, Raju,Ghosh, Munmun,Roy, Pronay,Ray, Jayanta K.
supporting information, p. 1479 - 1482 (2016/03/12)
A one-pot simple and concise methodology has been developed for synthesizing aromatic carboxylic anhydrides starting from easily accessible aromatic aldehydes using cuprous chloride as the catalyst and TBHP as the oxidant in DMSO solvent to garner moderate to good yields via radical pathway in short and convenient reaction time at room temperature.